A battery dimensional change detection system and associated methods provide battery “swell” detection capabilities for an electronic device. In this way, excessive dimensional changes that are detected lead to shutting off the power supplied by the battery. According to one aspect, a battery dimensional change detection system broadly includes a testing circuit, a voltage detection device, and a shut-off switch. The testing circuit is formed by one or more electrically conductive members and extends across an exposed portion of the battery, such that the circuit possesses first and second terminal ends. The voltage detection devices engages the first and second terminal ends to measure the voltage across the testing circuit. Selectively responsive to the particular voltage measurement value, the shut-off switch may prevent further battery discharge in the electronic device, thereby acting to inhibit further battery dimensional change.
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7. A method for shutting off the discharge of a battery in an electronic device, wherein the battery has an exposed portion and is operatively housed within the electronic device, and wherein a testing circuit interfaces with the battery, wherein the testing circuit includes a first terminal end, a second terminal end, and a portion that has a variable electrical resistance, the method comprising:
measuring the voltage across the testing circuit via the first terminal end and the second terminal end of the testing circuit, wherein the voltage is correlated with a change in an electrical resistance of the testing circuit; and
disconnecting the battery from a power circuit of the electronic device upon determining that:
a) the voltage exceeds a predetermined voltage value, or
b) the voltage exceeds a previously measured voltage value by a predetermined value.
1. A battery dimensional change detection system for a battery, wherein the battery has an exposed portion, and wherein the battery is operatively housed in an electronic device that receives electrical power from the battery, the system comprising:
a testing circuit formed by at least one electrically conductive member, wherein the testing circuit interfaces with the battery such that a dimensional change of the battery alters a cross-sectional area of the testing circuit, wherein the testing circuit includes a first terminal end and a second terminal end;
a voltage detection device configured for measuring the voltage across the testing circuit by engaging the first terminal end and the second terminal end of the testing circuit; and
a shut-off switch selectively responsive to a particular voltage measurement value by the voltage detection device to prevent further battery discharge in the electronic device.
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This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Systems and methods are provided for detecting the “swell” or dimensional change of a battery operable within an electronic device, and in response, shutting off the power supplied by the battery. According to one aspect, a battery dimensional change detection system broadly includes a testing circuit, a voltage detection device, and a shut-off switch. The testing circuit is formed by one or more electrically conductive members and extends across an exposed portion of the battery, such that the circuit possesses first and second terminal ends. The voltage detection devices engages the first and second terminal ends to measure the voltage across the testing circuit. Selectively responsive to the particular voltage measurement value, the shut-off switch may prevent further battery discharge in the electronic device, thereby acting to inhibit further battery dimensional change.
A method is provided in a further aspect for shutting off discharge of a battery operably housed within an electronic device. According to the method, a voltage is measured across a testing circuit coupled with the battery via first and second terminal ends of the testing circuit. Based on the particular voltage measurement value, the battery may be selectively disconnected from a power circuit of the electronic device. In one arrangement, the battery is disconnected in circumstances where the currently measured voltage value exceeds a predetermined voltage value. In another arrangement, disconnection of the battery occurs in circumstances where the currently measured voltage value exceeds a previously measured voltage value by a predetermined value.
Additional advantages and features of the invention will be set forth in part in a description which follows, and in part will become apparent to those skilled in the art upon examination of the following, or may be learned by practice of the invention.
The present invention is described in detail below with reference to the attached drawing figures, wherein:
Embodiments of the present invention provide a solution for mitigating battery “swell” by a dimensional change detection system coupled with the battery. For instance, a discharging battery may encounter an internal gaseous buildup due to exothermic chemical reactions between battery components. The electrical conductivity (and by analogy, resistivity) properties of the testing circuit are measured during battery discharge in powering an electronic device. Due to the configuration of the testing circuit, the electrical properties of the circuit are necessarily altered by dimensional changes of the battery during discharge, specifically “swelling” of the battery. Electrical current is passed through one or more electrically conductive members that form the testing circuit, the conductive members being, in one embodiment, disposed on the outer surface of the battery. It should be understood that the term “conductive members” is meant to include those members made of material classified as conductive (e.g., copper or other metals) or semi-conductive (e.g., silicon-based).
In one arrangement, changes in the measured resistivity across the testing circuit are noted. In conjunction with other known factors that may affect resistivity of the circuit (e.g., change in temperature of the conductive members during electronic device operation), the change in resistivity may be correlated with a change in both the cross-sectional dimension and the length of the testing circuit, indicating that a “swelling” battery is applying a force on the circuit. For instance, in the exemplary arrangement shown in
With continued reference to
In one arrangement, the testing circuit 100 may be coupled with the battery 1000 via flanged anchor portions 108 adhered to or otherwise attached with opposed sidewalls 1004 of the battery 1000. In an alternative arrangement, the testing circuit 100 may be formed into an exterior cover 1006 of the battery 1000 with the first and second terminal ends 104 and 106 remaining exposed. In yet another arrangement, the testing circuit 100 may be formed or mounted into a receptacle of an electronic device (not shown) where the battery 1000 is housed, such that upon normal battery installation, the testing circuit 100 abuts the exposed portion 1002 of the battery 1000. In any case, the testing circuit 100 should be electrically insulated from the surrounding environment and physically interface with the battery 1000 when installed in the respective electronic device to the extent necessary to be affected by dimensional changes of the battery 1000. For instance, in the arrangement where the testing circuit is attached with or formed into the exterior cover 1006 of the battery 1000, portions of the battery contacting the testing circuit should be formed of non-conductive materials.
As referenced above, the electrical properties of the testing circuit 100 are measured to determine if dimensional changes of the battery are occurring during operation in the respective electronic device. In one schematic arrangement illustrated in
Accordingly, in one operational scheme, a small electrical current is supplied by a power circuit 2000 of the electronic device to the testing circuit 100 when the battery is in normal operational (discharge) mode. A voltmeter 2002 measures the voltage across the testing circuit 100 via engagement with the first and second terminal ends 104 and 106. When the measured voltage exceeds a certain predetermined threshold value, or increases sufficiently in value compared to a previously measured value, the voltmeter 2002 triggers a shut-off switch 2004 to disconnect the battery 1000 from the power circuit 2000 of the electronic device.
Many different arrangements of the various components depicted, as well as components not shown, are possible without departing from the spirit and scope of the present invention. Embodiments of the present invention have been described with the intent to be illustrative rather than restrictive. Alternative embodiments will become apparent to those skilled in the art that do not depart from its scope. A skilled artisan may develop alternative means of implementing the aforementioned improvements without departing from the scope of the present invention. It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations and are contemplated to be within the scope of the claims. Additionally, it is intended that references to components of the present invention in the singular encompasses one or more of such components.
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